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CO 2 laser system

CO 2 laser system. M. Polyanskiy, I. Pogorelsky , M. Babzien , and V. Yakimenko. Historical perspective. 200 MeV Protons. 20 MeV Protons. 30 TW 3 TW 300 GW 30 GW 3 GW. LWFA. VLA. High gradient IFEL. Thomson X-ray imaging. Ion and Proton source. LACARA. PASER.

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CO 2 laser system

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  1. CO2 laser system M. Polyanskiy, I. Pogorelsky, M. Babzien, and V. Yakimenko

  2. Historical perspective 200 MeV Protons 20 MeV Protons 30 TW 3 TW 300 GW 30 GW 3 GW LWFA VLA High gradient IFEL Thomson X-ray imaging Ion and Proton source LACARA PASER Nonlinear Thomson scattering EUV source STELLA HGHG Inverse Cherenkov accelerator Thomson X-ray source IFEL accelerator 1995 2000 2005 2010 2015 CO2 laser

  3. Ion acceleration C. Palmer et al. Phys. Rev. Lett. 106:014801 (2011) • Relativistically – strong (ao~10) 100-TW CO2 laser will be a good driver for “bubble” LWFA Ponderomotive force drives plasma wave The ponderomotive energy of the electron in the optical field is proportional to2. Assuming l and ncras normalization parameters, CO2 laser will produce a bubble of 1000 times bigger volume, at 100 times smaller plasma density, 10 times higher charge, and better control over e-beam parameters and phasing between accelerator stages. Electron bunch Laser pulse CO2 laser

  4. Our priorities {1,2} RELIABLE POWER 1 POWER 2 RELIABILITY CO2 laser

  5. ATF’s CO2 laser 10-ns HV 14-ps YAG 5-ps SH-YAG MAIN AMPLIFIER OSCILLATOR PREAMPLIFIER REGEN 5 ps 5 J 200 ns 20 mJ Plasma mirror Pockelscell Kerr cell CO2 laser

  6. Increasing power: which way? Brutal: add another amplifier section vs. Smart: shorten the pulse, improve energy extraction CO2 laser

  7. First steps: isotopic active medium Simulations Experiment Natural CO2 Isotopic CO2 CO2 laser

  8. Optics Express 19:7717 (2011) CO2 laser

  9. First steps: solid-state injector • SIMPLICITY & RELIABILITY • SHORT PULSE • HIGH PULSE ENERGY • HIGH CONTRAST • BETTER ENERGY EXTRACTION SOLID-STATE INJECTOR MAIN AMPLIFIER REGEN 1-2 ps 10+ J 400 fs 40 µJ

  10. Challenge: non-linear response of IR materials Kerr lensing (spatial effect) low n high n low n Pulse chirping (temporal effect) CO2 laser

  11. Case study: n2 killing the pulse in regen 5-cm CdTe in a laser cavity CO2 laser

  12. Regen re-configuration BEFORE: <1 mJ IN OUT λ/4 Polarizing splitter ZnSe, 2 mm (290×10-16cm2/W) Pockelscell CdTe, 50 mm (-3000×10-16 cm2/W) NaCl, 25 mm x 2 (4.4×10-16cm2/W) OUT AFTER: 10 mJ YAG R=82% IN Ge, 0.5 mm (2800×10-16cm2/W) NaCl, 25 mm x 2 (4.4×10-16 cm2/W) CO2 laser

  13. Next step: chirped pulse amplification PRELIMINARY TEST STRETCHER COMPRESSOR CO2 laser

  14. Saturation effects in the active medium Pyrocamera Diffractive grating 6.2 ps INPUT 71 GHz SPECTROMETER OUTPUT Linear regime (1.1 mJ→ 1.4 J) 6.1 ps 72 GHz 2.7 ps (?) OUTPUT Non-linear regime (3.2 mJ→2.7 J) 160 GHz CO2 laser

  15. Model simulations SPECTRUM PULSE PROFILE INPUT 5 ps 88 GHz (5 ps) OUTPUT 3.2 ps (2.6 ps ?) 170 GHz CO2 laser

  16. Main amplifier status • Major failure: break-down of HV fit-through between high-pressure vessel and water capacitor • Currently operating at reduced pressure and discharge voltage • Amplification loss is compensated by increasing number of passes • New mirror system featuring reliable remote control implemented CO2 laser

  17. Long-term vision: compression to sub-ps Pulse profile Spectra Laser-induced ionization shifts phase of the wave resulting in a chirp. Subsequent pulse compression results in 3~4 times pulse shortening. Gordienko et al. Quantum Electronics, 39:663 (2009) CO2 laser

  18. Long-term vision: optical pumping • Solid-state ErCr:YSGG (2.79 μm) laser • High pressure • No CO2 dissociation in the discharge • Direct and fast pumping of laser transition in CO2 • N2-free mixture • Efficient energy extraction in single pass • Eliminating self-lasing • An amplifier producing ~5 mJ output in a 3-ps pulse when pumped by a 300-mJ ErCr:YSGGlaser demonstrated theoretically Gordienko et al. Quantum Electronics, 40:1118 (2010) CO2 laser

  19. Summary • Priority: support user’s experiments via providing reliable power • Approach to increasing power: get maximum from available amplifiers • Isotopic regenis routinely operated providing a true single pulse • New all-solid-state injector will improve system performance and reliability • Non-linear effects in optical materials becoming an issue. Regen re-configuration provided 10 mJ (2 GW) pulses before the main amplifier • Chirped-pulse amplification was a breakthrough in solid-state lasers; we expect similar impact on ultrashort-pulse gas lasers • Non-linear amplification regime in the main amplifier presumably provide pulse shortening to ~3 ps (well below resolution limit of our 20+ years old streak camera) • Main amplifier recovered from a major failure; new remotely-controlled mirror system implemented • Long-term roadmapis being considered CO2 laser

  20. P.S. Polyanskiy and Babzien “Ultrashort Pulses” in “CO2Laser - Optimization and Application”, InTech (2012) CO2 laser

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